Your search keyword '"Vega-Cantu YI"' showing total 6 results

1. Evaluation of freezing, ultra-cold freezing, and freeze-drying on the main components of human breast milk

Author

Dávila-Caraballo, GJ, Serrato-Márquez, E., Grimaldo-Rivas, MD, Chuck-Hernández, C., Vega-Cantú, YI, Ortega-Alonzo, SE, Coronado-Cerda, E., and Urrutia-Baca, VH

Published

2024

2. Drug-Eluting, Bioresorbable Cardiovascular Stents─Challenges and Perspectives.

Author

Vallejo-Zamora JA, Vega-Cantu YI, Rodriguez C, Cordell GA, and Rodriguez-Garcia A

Abstract

Globally, the leading causes of natural death are attributed to coronary heart disease and type 1 and type 2 diabetes. High blood pressure levels, high cholesterol levels, smoking, and poor eating habits lead to the agglomeration of plaque in the arteries, reducing the blood flow. The implantation of devices used to unclog vessels, known as stents, sometimes results in a lack of irrigation due to the excessive proliferation of endothelial tissue within the blood vessels and is known as restenosis. The use of drug-eluting stents (DESs) to deliver antiproliferative drugs has led to the development of different encapsulation techniques. However, due to the potency of the drugs used in the initial stent designs, a chronic inflammatory reaction of the arterial wall known as thrombosis can cause a myocardial infarction (MI). One of the most promising drugs to reduce this risk is everolimus, which can be encapsulated in lipid systems for controlled release directly into the artery. This review aims to discuss the current status of stent design, fabrication, and functionalization. Variables such as the mechanical properties, metals and their alloys, drug encapsulation and controlled elution, and stent degradation are also addressed. Additionally, this review covers the use of polymeric surface coatings on stents and the recent advances in layer-by-layer coating and drug delivery. The advances in nanoencapsulation techniques such as liposomes and micro- and nanoemulsions and their functionalization in bioresorbable, drug-eluting stents are also highlighted.

Published

2022

3. Dental Applications of Carbon Nanotubes.

Author

Castro-Rojas MA, Vega-Cantu YI, Cordell GA, and Rodriguez-Garcia A

Subjects

Acrylic Resins chemistry, Acrylic Resins therapeutic use, Humans, Silicon Dioxide chemistry, Silicon Dioxide therapeutic use, Surface Properties, Drug Carriers chemistry, Drug Carriers therapeutic use, Materials Testing, Nanotubes, Carbon chemistry, Resin Cements chemistry, Resin Cements therapeutic use

Abstract

Glass ionomer cements and resin-based composites are promising materials in restorative dentistry. However, their limited mechanical properties and the risk of bulk/marginal fracture compromise their lifespan. Intensive research has been conducted to understand and develop new materials that can mimic the functional behavior of the oral cavity. Nanotechnological approaches have emerged to treat oral infections and become a part of scaffolds for tissue regeneration. Carbon nanotubes are promising materials to create multifunctional platforms for dental applications. This review provides a comprehensive survey of and information on the status of this state-of-the-art technology and describes the development of glass ionomers reinforced with carbon nanotubes possessing improved mechanical properties. The applications of carbon nanotubes in drug delivery and tissue engineering for healing infections and lesions of the oral cavity are also described. The review concludes with a summary of the current status and presents a vision of future applications of carbon nanotubes in the practice of dentistry.

Published

2021

4. Influence of Controlled Cooling on Crystallinity of Poly (L-Lactic Acid) Scaffolds after Hydrolytic Degradation.

Author

Vazquez-Armendariz J, Tejeda-Alejandre R, Rodriguez-Garcia A, Vega-Cantu YI, Mendoza-Buenrostro C, and Rodriguez CA

Abstract

The use of hybrid manufacturing to produce bimodal scaffolds has represented a great advancement in tissue engineering. These scaffolds provide a favorable environment in which cells can adhere and produce new tissue. However, there are several areas of opportunity to manufacture structures that provide enough strength and rigidity, while also improving chemical integrity. As an advancement in the manufacturing process of scaffolds, a cooling system was introduced in a fused deposition modeling (FDM) machine to vary the temperature on the printing bed. Two groups of polylactic acid (PLA) scaffolds were then printed at two different bed temperatures. The rate of degradation was evaluated during eight weeks in Hank's Balanced Salt Solution (HBSS) in a controlled environment (37 °C-120 rpm) to assess crystallinity. Results showed the influence of the cooling system on the degradation rate of printed scaffolds after the immersion period. This phenomenon was attributable to the mechanism associated with alkaline hydrolysis, where a higher degree of crystallinity obtained in one group induced greater rates of mass loss. The overall crystallinity was observed, through differential scanning calorimetry (DSC), thermo gravimetric analysis (TGA), and Fourier transformed infrared spectroscopy (FTIR) analysis, to increase with time because of the erosion of some amorphous parts after immersion.

Published

2020

5. Effect of magnesium and iron on the hydration and hydrolysis of guar gum.

Author

Vega-Cantu YI, Hauge RH, Norman LR, Powell RJ, and Billups WE

Subjects

Carbohydrate Conformation, Hydrogen-Ion Concentration, Hydrolysis, Molecular Sequence Data, Plant Gums, Temperature, Time Factors, Viscosity, Galactans chemistry, Iron chemistry, Magnesium chemistry, Mannans chemistry

Abstract

The effect that magnesium and iron have on the hydration and hydrolysis of guar gum at pH 12 was studied as a function of viscosity. It was found that small concentrations of magnesium do not affect the dissolution ratio of guar but significantly decrease hydrolysis at high temperatures. These results suggest that Mg(OH)(2) forms an adduct with the polysaccharide that prevents thermal hydrolysis of the guar. Viscosity measurements recorded in the presence of iron at pH 12 show that ferric iron inhibits hydration or dissolution of guar and may accelerate chain scission of fully hydrated guar when solutions are heated in an autoclave at 121 degrees C.

Published

2006

6. Effect of film thickness on the performance of photopolymers as holographic recording materials.

Author

Boyd JE, Trentler TJ, Wahi RK, Vega-Cantu YI, and Colvin VL

Abstract

An important issue in developing applications for photopolymers in holography is the effect of film thickness on recording properties. Now it is possible to create these samples with a much wider range of thickness (d = 20-1400 mum) than was previously available. We exploit these recent advances in photopolymer processing to systematically evaluate how the dynamic range of a photopolymer depends on its thickness. The results illustrate that sample performance increases linearly with thickness as predicted by standard models of volume holography. However, above a critical thickness sample performance degrades, and the angular response of recorded plane-wave holograms shows evidence of grating curvature. These distortions are likely the result of photopolymer shrinkage, which in thicker samples occurs in a nonuniform fashion. This problem limits the performance of these photopolymers and is likely to be an issue for any photopolymer that undergoes comparable polymerization shrinkage.

Published

2000